EP0011838A1 - Mould closing device for an injection moulding machine - Google Patents

Abstract

A mold-closing device for an injection-molding machine has a main piston connected to the mold-carrying plate of a movable mold half and is provided with a pressure-multiplying piston which closes a passage between sides of the main piston to render effective the differential action of the multiplier piston. The multiplier piston can be shifted prior to the main piston by a time-delay device in the pressure lines and/or by a mechanical element.

Description

The invention relates to a mold closing device for an injection molding machine with a hydraulically displaceable mold carrier plate, the hydraulic drive device of which comprises a double-acting master piston, a master cylinder chamber divided by the master piston into an opening-side and a closing-side master cylinder space, and a rapid traverse device which is operatively connected to the master piston the opening-side and the closing-side master cylinder space are connected to one another by a closable through-channel located in the main piston. A mold closing device of this type is known from DE-OS 1 778 952, in which the cylinder spaces located in front of and behind the main piston are connected to one another by a channel. Although this arrangement has the advantage that the circulating amounts of pressure medium to be moved back and forth to the two active surfaces of the piston can be kept small, it has the disadvantage, however, that a separate one for the circulation valve which serves to close the channel during the printing phase Control device is needed. In addition, the main piston requires a dimensioning of its active surface corresponding to the existing system pressure, which results in relatively large dimensions of the main piston.

The invention has for its object to provide a mold closing device of the type mentioned, which results in a compact design and which only requires pressure medium with system pressure to control and act on the main piston.

This object is achieved according to the invention in that the main piston has a preferably coaxial cylinder space, in which a pressure booster piston is axially displaceable, which divides the cylinder space into an opening-side subspace and a closing-side subspace, that the through-channel is designed so that the part on the closing side a connection opening to the opening master cylinder chamber and a circulation opening which can be closed by axial displacement of the pressure booster piston to the master cylinder chamber on the closing side has that the pressure booster piston has two oppositely directed piston surfaces of different sizes to generate an increased pressure, of which the larger piston surface faces the opening side chamber and the smaller piston surface faces the closing side chamber, so that the smaller piston area only results after the circulation opening has been closed by a sealing piston which projects from the smaller piston area and is firmly connected to the pressure booster piston and that the opening-side part space and the opening-side master cylinder space are connected to a common pressure line via connecting lines.

In addition, the invention has the further advantage that the pressure booster and the circulation valve are combined to form a functional unit. Furthermore, all _'control units have to be dimensioned only to the system pressure.

In a preferred embodiment, the rapid traverse device can consist of a hydraulically actuable rapid traverse piston located in a rapid traverse cylinder space, which is arranged lying on an axis with the double-acting main piston, the main piston and the rapid traverse piston being able to form a unit, which is particularly compact hydraulic drive device for the mold carrier plate results.

The pressure intensifier piston can be provided with a separate actuator for its displacement into a position closing the through-channel, which can consist of an axially displaceable actuating piston which can be arranged in an actuating cylinder adjoining the opening-side subspace with connection to the pressure line.

The connection to the pressure line leading to the opening-side master cylinder space preferably has a time delay element, as a result of which an exact temporal separation of the functions to be carried out by the pressure booster piston, namely the closing of the passage opening with subsequent build-up of increased pressure, can be achieved.

Further features and advantages of the invention will become apparent from the following description based on the drawing and in conjunction with the claims.

• Fig. 1 eine Schnittansicht durch eine hydraulische Antriebsvorrichtung für eine Formträgerplatte
• Fig. 2 eine Teilansicht einer anderen AusfUhrungsform der Erfindung
• Fig. 3 eine Teilansicht durch eine weitere Ausgestaltung der Ausführungsformen nach den Figuren 1 und 2.

Show it:

• Fig. 1 is a sectional view through a hydraulic drive device for a mold carrier plate
• Fig. 2 is a partial view of another embodiment of the invention
• 3 shows a partial view through a further embodiment of the embodiments according to FIGS. 1 and 2.

In the embodiment according to FIG. 1, a mold carrier plate is denoted by 1, to which a partly shown mold half 2 is fastened. The mold carrier plate 1 is guided back and forth on guide columns 3 in the direction of the arrow 4 in the mold closing and opening direction. The guide columns 3 are rigidly connected to a fixed stand plate 5, in which the hydraulic elements for driving the mold carrier plate 1 are contained.

The hydraulic elements essentially consist of a master piston 6, which divides a master cylinder space into an opening-side master cylinder space 7 and a closing-side master cylinder space 8. The main piston 6 is extended into a pressure column 9 which is attached to the mold carrier plate 1.

Piston rods 1.0 of rapid traverse pistons 11 also act on the mold carrier plate 1, which are also arranged in rapid traverse cylinder spaces 12 arranged in the stand plate 5.

The main piston 6 has a coaxial cylinder space, in which a pressure booster piston (or multiplier) 13 is guided in an axially displaceable manner and which divides the cylinder space into an opening-side partial space 14 and a closing-side partial space 15.

The opening-side master cylinder chamber 7 and the closing-side master cylinder chamber 8 are connected by a through-channel arranged in the main piston 6, which results from a connecting opening 16, the closing-side sub-chamber 15, a circulation opening 17 and a further connecting opening 18 leading into the closing-side main cylinder chamber 8.

The pressure booster piston has two oppositely directed piston surfaces of different sizes, of which the larger piston surface 19 closes the opening-side subspace 14 and the smaller piston surface 20 closes the closing-side subspace 15. A locking piston 21, which forms a unit with the pressure booster piston 13 and whose cross-sectional area corresponds to the cross-sectional area of the circulation opening 17, projects from the smaller piston surface 20.

The opening-side subspace 14 and the opening-side master cylinder space 7 are connected via connecting lines 22 and 23 to a common pressure line 24 carrying pressure medium under system pressure. A pressure line 25 which can be acted upon for the tear-away stroke leads to the master cylinder chamber 8 on the closing side. The connecting lines 22 and 23 have check valves 26 and 27 blocking the return direction of the pressure medium (arrows with broken lines), of which the latter is a time delay element in the form of a check valve 27 in the conveying direction inhibiting spring 28. A pressure switching valve 29 for relieving the pressure booster piston 13 for the mold opening process is arranged in a bypass arrangement with the check valve 26.

In the embodiment according to FIG. 2, the rapid traverse piston 11 and the main piston 6 form a unit and act together on the mold carrier plate 1 via the pressure column 9.

3 shows a pressure booster piston 13 arranged in the main piston 6 and preceded by an actuating piston 30. This is axially displaceably mounted in its cylinder space adjacent to the opening-side partial space 14, into which a connection 31 leads from the pressure line 24. An extension part 32 projects from the actuating piston 30 into the opening-side subspace 14 so that it abuts the pressure booster piston 13 and can bring it into a position closing the circulation opening 17.

In the operation of the embodiment according to FIG. 1, the pressure line 24 is pressurized with pressure medium under system pressure after the rapid traverse feed is completed by the rapid traverse piston 11. It passes through the connecting lines 22 and 23 into the opening-side subspace 14 and into the opening-side master cylinder space 7 and via the connecting opening 16 into the closing-side subspace 15. Due to the fact that the opening-side subspace 14 has a smaller volume than the opening-side master cylinder space 7 and the closing-side subspace 15, the pressure medium in the opening-side subspace 14 is more effective, so that the pressure booster piston 13 is first shifted and closes the circulation opening 17 with its locking piston 21. The functional sequence that the pressure booster piston 13 is first moved before the movement of the main piston 6 can be further improved by arranging a time delay element in the connecting line 23 or in the check valve 27. The pressure medium on the main piston 6 now comes into play, as a result of which the force required for closing and holding is brought to the mold carrier plate 1 via the pressure column 9. This force is further increased by the pressure booster piston 13, since this also has the effect of its differential pressure areas. With unchanged exposure to pressure medium under system pressure, a pressure increase in the ratio of the larger piston area 19 to the smaller piston area 20 of the pressure booster piston 13 is thus achieved. A backflow of the pressure medium through the check valves 26 and 27 is prevented. After completion of the injection molding process, the opening-side subspace 14, the closing-side subspace 15 and the opening-side master cylinder space 7 are relieved by opening the pressure switching valve 29, after which the pressure build-up via the pressure line 25 Tearing stroke is initiated. Subsequently, the mold carrier plate 1 is moved back into the starting position or opening position by the rapid-motion pistons 11.

In the operation of the embodiment according to FIG. 3, the pressure booster piston 13 is first mechanically pushed by the adjusting piston 30 into a position closing the circulation opening 17 during the closing process, whereupon the excessive pressure brought about by the pressure booster piston 13 sets in to close and hold the injection mold halves. It may be advantageous to provide both the connection leading to the opening-side subspace 14 and the connection leading to the opening-side master cylinder space 7 with a time delay element.

Claims (8)

1. Mold closing device for an injection molding machine with a hydraulically displaceable mold carrier plate, the hydraulic drive device of which comprises a double-acting main piston, a main cylinder space divided by the main piston into an opening-side and a closing-side master cylinder space, and a rapid traverse device which is operatively connected to the main piston and in which the opening-side and the the master cylinder chamber on the closing side is connected to one another by a closable through-channel located in the main piston, characterized in that the main piston (6) has a preferably coaxial cylinder chamber in which a pressure booster piston (13) is axially displaceably guided and leads the cylinder chamber into an opening-side sub-chamber (14 ) and divides it into a sub-chamber (15) on the closing side so that the through-channel is designed in such a way that the sub-chamber (15) on the closing side has a connecting opening (16) to the opening-side master cylinder chamber (7) and a by means of axial displacement of the pressure booster piston (13) closable circulation opening (17) to the master cylinder chamber (8) on the closing side has that the pressure booster piston (13) to generate an increased pressure two opposite ge Directed piston surfaces of different sizes, of which the larger piston surface (19) faces the opening-side sub-space (14) and the smaller piston surface (20) faces the closing-side sub-space (15), that the smaller piston surface (20) only moves after the circulation opening (17 ) from a smaller piston surface (20) protruding, with the pressure intensifier piston firmly connected sealing piston (21) and that the opening-side part space (14) and the opening-side master cylinder space (7) via connecting lines (22) and (23) to a common one Pressure line (24) are connected. 2. Apparatus according to claim 1, characterized in that the rapid traverse device consists of a hydraulically actuated rapid traverse piston (11) located in a rapid traverse cylinder chamber (11) and is arranged lying on an axis with the double-acting main piston (6). 3. Apparatus according to claim 2, characterized in that the double-acting main piston (6) and the rapid traverse piston (11) form a unit. 4. The device according to claim 1, characterized in that the pressure booster piston (13) is a separate one Has actuator for its displacement in a position closing the circulation opening (17). 5. The device according to claim 4, characterized in that the actuator consists of an axially displaceable, in a, on the opening-side sub-space (14) adjacent cylinder space bearing actuating piston (30) which projects into the opening-side sub-space (14), the pressure booster piston (13) actable extension part (32). 6. The device according to claim 1, characterized in that the connection line (23) leading to the opening-side master cylinder space (7) has a time delay element. 7. The device according to claim 6, characterized in that the Zeitver delay element from a spring-loaded valve (27, 28) acting counter to the conveying direction of the pressure medium .. 8. The device according to claim 6, characterized in that the time delay element consists of a throttle arranged in the connecting line (23).

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